Background

Klebsiella pneumoniae is a frequent nosocomial pathogen, with the multidrug-resistant (MDR) K. pneumoniae being a major public health concern, frequently causing difficult-to-treat infections worldwide. The aim of this study was to investigate the molecular characterization of clinical MDR Klebsiella pneumoniae isolates.

Results

All the isolates co-harbored 3 or more resistance determinants. OqxAB, CTX-M-type ESBLs and RmtB were the most frequent determinants, distributed among19 (70.4%),18 (66.7%) and 8 (29.6%) strains. Fourteen isolates harbored class 1 integrons, with orfD-aacA4 being the most frequent gene cassette array. Class 3 integrons were less frequently identified and contained the gene cassette array of blaGES-1-blaOXA-10-aac(6′)-Ib. IncFII replicon was most commonly found in this collection. One cluster was observed with ≥80% similarity among profiles obtained by PFGE, and one sequence type (ST) by MLST, namely ST11, was observed in the cluster.

Conclusion

K. pneumoniae carbapenemase (KPC)–producing ST11 was the main clone detected. Of particular concern was the high prevalence of multiple resistance determinants, classs I integrons and IncFII plasmid replicon among these MDR strains, which provide advantages for the rapid development of MDR strains.

Klebsiella pneumoniae is an opportunistic pathogen associated with both community-acquired and nosocomial infections, including pneumonia, urinary tract infections, septicemia and wound infections, with the increasingly multidrug-resistant (MDR) K. pneumoniae being a major public health concern.

Although the high prevalence of these resistance determinants has been reported among MDR K. pneumoniae strains [6, 7], there is little information available on the distribution of integrons and plasmid replicons among these strains, and limited data on the genetic relationship between these strains.

The aim of this study therefore was to investigate the prevalence of frequently reported antimicrobial resistance determinants among the 27 clinical MDR K. pneumoniae isolates, to explore the distribution of integrons and plasmid replicons, as well as to analyze the genetic clonality by pulse field gel electrophoresis (PFGE) and multi-locus sequence typing (MLST).

Bacterial isolates

A total of 27 non-duplicate MDR K. pneumoniae isolates simultaneously displaying resistance to cefotaxime, amikacin and levofloxacin were collected from our hospitals from March to July 2011(Susceptibility to antimicrobial agents was determined using Kirby–Bauer’s disc diffusion method and the results were analyzed and interpreted according to CLSI guidelines [8]). Among them, 12 strains were resistant to imipenem. The clinical sources of these specimens include sputum (n = 13), urine (n = 4), blood (n = 7), and wound secretions (n = 3). Among these 27 isolates, 2 strains originated from community-acquired infections, defined as the pathogen being isolated within 48 h after hospital admittance. The other 25 ones were from nosocomial infections, where the pathogens were isolated more than 48 h after being admitted to a hospital.

Detection of antimicrobial resistance determinants

DNA templates were prepared by the boiling method. All the isolates were analyzed for the presence of bla ESBLs (bla CTX, bla TEM, bla SHV, bla VEB, and bla OXA) [9], PMQRs (qnrA, qnrB, qnrC, qnrD, qnrS, aac (6′)-Ib-cr, and qepA) [10], and 16S-RMTases (armA, npmA, rmtA, rmtB, rmtC, rmtD, and rmtE) [11]. The 12 strains resistant to imipenem were further analyzed for CHβLs endocing genes (bla KPC, bla OXA-48, bla IMP, bla VIM, bla NDM, bla DIM, bla SPM, and bla SIM) [12]. All genes were screened by multiplex PCR followed by single PCR for gene confirmation. Positive products were further purified with a DNA purification kit and then sent to the Majorbio Company (Shanghai, China) for sequencing. Sequences were analyzed by using the Chromas-Pro application and BLAST (http://www.ncbi.nlm.nih.gov/BLAST).

Detection of integrons

Integrons were detected by PCR amplification of class 1, 2, and 3 integrase-specific int-1, int-2, and int-3 genes, as described previously [13]. To reveal the gene cassettes of the variable region of integrons, the variable region of class 1 and 3 integrons were further amplified and purified, and then sequenced to determine their gene cassette composition. The resulting nucleotide sequences and deduced protein sequences were analyzed with the BLAST and FASTA programs of the National Center for Biotechnology Information (http://www.ncbi.nlm.nhi.gov).

Pulsed-field gel electrophoresis

Clonal relatedness of 27 K. pneumoniae isolates was analyzed by pulsed-field electrophoresis (PFGE) as described [15]. Prepared genomic DNA was digested using the restriction endonuclease Xba I (Fermentas, ABI, Germany), and DNA fragments were separated in a PFGE CHEF-DR III system (Bio-Rad Laboratories, Hercules, CA) in 0.5× Tris-borate-EDTA buffer at 120 V for 19 h, with pulse times ranging from 2.2 s to 54.2 s. The banding patterns were analyzed by the BioNumerics software (Applied Math, Sint-Maten-Latem, Belgium). Cutoff lines at 65% and 80% were used to analyze genetic relatedness.

Multi-locus sequence typing

Genotyping for the 27 MDR strains was further determined by multi-locus sequence typing (MLST) analysis. MLST with 7 genes (gapA, infB, mdh, pgi, phoE, rpoB, and tonB) was performed according to Diancourt et al. [16]. Alleles and sequence types (STs) were assigned by using the MLST database (http://www.pasteur.fr/mlst/Kpneumoniae.html).

Furthermore, all the isolates co-harbored 3 or more resistance determinants. The PMQRs were present in 19 out of the 22 ESBL-carrying K. pneumoniae isolates. Of the 11 KPC-positive MDR K. pneumoniae isolates, 7 co-carried rmtB or armA.

Prevalence of integrons

Integron analysis showed that 14 isolates carried class 1 integrons; 6 carried class 3 integrons; and 2 contained both of class 1 and 3 integrons (Figure 1). No class 2 integrons were found. Sequencing analysis for intI1-positive strains revealed that the cassette arrays of class 1 integron include orfD-aacA4 (n = 10 strains) and aad5-dfrA17 (n = 4 strains). Moreover, the variable regions in class 3 integrons of all the 6 isolates were the same as those comprising blaGES-1-blaOXA-10-aac(6′)-Ib, which has been identified in an earlier study [17].

Clonal relatedness

According to the PFGE patterns of the isolates (Figure 1), 27 different clonal patterns were observed among the 27 MDR K. pneumoniae isolates with ≥65% similarity.

One cluster of 7 closely related isolates was found that exhibited ≥80% similarities, these isolates were identified to be ST11 clones.

Sequence types for the K. pneumoniae isolates

MLST was conducted to determine the extent of genotypic diversity among the K. pneumoniae isolates. Fifteen different STs were identified. The most dominant ST was ST11 (29.6%, 8/27), followed by ST686 (14.8%, 4/27), ST1 (7.4%, 2/27), ST756 (7.4%, 2/27). These 4 STs accounted for 59.3% (16/27) of the total isolates. Among the STs identified, ST415, ST186, ST276, and ST866 have previously not been identified to be MDR strains.

MDR K. pneumoniae strains have caused major therapeutic problems worldwide. The increasing prevalence of clinical MDR isolates has been associated with higher morbidity and mortality rates, posing a considerable threat to public health. In this study, we provide the current data on the molecular characterization of MDR K. pneumoniae isolates isolated from different clinical samples of hospitalized patients.

Our study revealed a wide distribution of diverse resistance determinants among the MDR K. pneumoniae strains. The most prevalent determinants were oqxAB genes, which have been reported to be the most frequent PMQRs in K. pneumoniae isolates [18]. CTX-M has been found to be widely disseminated among clinical Enterobacteriaceae such as Escherichia coli and K. pneumoniae[19], the even higher prevalence of bla CTX-M among our strains corresponds with an earlier report showing that CTX-M–producing strains are generally MDR ones [19]. Furthermore, in line with the previous investigation [20], KPC is highly prevalent among our strains, which also demonstrated that the production of KPC-type carbapenemases was the most prevalent carbapenem resistance mechanism in K. pneumoniae isolates. In addition, the widely distributed 16S-RMTase encoding genes in our MDR strains have been previously reported in China [21], together with AAC (6′)-Ib-cr and AAC (6′)-Ib accounting for the amikacin resistance. Recently, co-production of 16S rRNA methylases (ArmA and RmtB) and KPC were frequently reported in Enterobacteriaceae[22], which was also observed in our study, leading to few choices for antimicrobial treatment. Notably, there seems to be an intimate association between the occurrence of oqxAB and ESBLs; a similar phenomenon was noted for 16S-RMTase and β-lactamase. Such a frequent co-existence of 16S-RMTase with PMQRs and β-lactamase among MDR K. pneumoniae isolates in our study suggests a horizontal dissemination of these determinants amongst clinical MDR K. pneumoniae isolates. These MDR strains co-carrying diverse and numerous multiple resistance determinants may impose limitations in the therapeutic options available for the treatment of infections.

Epidemic resistance plasmids including IncFII, IncA/C, IncL/M, IncN and IncI1 plasmids has been worldwide detected in Enterobacteriaceae of different origin and sources [23]. In our study, the wide distribution of IncFII plasmid replicon is in accordance with the previous studies showing that IncFII plasmid replicons were most frequently detected in CTX-M-producing enterobacterial isolates in China and in Europe [24, 25]. Furthermore, other plasmid replicons such as IncN, IncI1, IncY and IncA/C distributed among our strains have also been previously reported [26, 27]. Additionally, the widely prevalent IncFII plasmid replicons and class I integrons identified in our study indicate that they might be playing an important role in attributing MDR to the clinical K. pneumoniae isolates. It is noteworthy that class 3 integrons were also detected among our strains. which is also reported earlier by Qi et al. in 2011 [28], showing the presence of class 3 integrons in MDR K. pneumoniae isolates from clinical settings in China, since class 3 integrons have also been found and characterized in Europe [29].

The genetic diversity of our isolates revealed that most isolates were of different strains, indicating the ease of transmission of these resistance determinants between bacterial species by mobile elements. This has been partially confirmed by the high prevalence of integrons and plasmid replicons in our study. However, it seems that the epidemic dissemination of the major clone ST11 producing bla KPC also played an additional role in our study, this corresponds with the report that ST11 is a truly international sequence type and associated with KPC [30]. Which is partly different from the KPC-producing K. pneumoniae clonal complex 258 (ST258, ST512, and ST101) in Europe and USA [31, 32]. Of note, the other STs such as ST415, ST186, ST276, and ST866 have not been previously identified to be MDR clones. Such a high heterogeneity of ST clones observed may further indicate the role of plasmids and integrons in the development of clinical MDR isolates.

In summary, our study showed that clinical MDR K. pneumoniae isolates may result mainly from the horizontal dissemination of multiple resistance determinants and the clonal dissemination of MDR ST11 strains–producing KPC-2, which alerts us the emergency and necessity to vigorously implement the infection control practice to prevent the dissemination of these MDR isolates in the healthcare settings.

Acknowledgment

This study is supported by Nan Jing Medical Science and Technique Development Foundation (grant no. QRX11191). We sincerely thank the EU Reference Laboratory for antimicrobial resistance of National Food Institute of Technical University of Denmark for providing the positive controls for our experiments.

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Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

XC performed experimental work and drafted manuscript; XX and ZZ analyzed the study data; JC and HS provided interpretation of data; KZ conceived the study and provided data interpretation. All authors read and approved the final manuscript.

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